ML20033F092
| ML20033F092 | |
| Person / Time | |
|---|---|
| Site: | Peach Bottom  |
| Issue date: | 11/20/1989 |
| From: | GENERAL PHYSICS CORP. |
| To: | |
| Shared Package | |
| ML20033F091 | List: |
| References | |
| GP-R-312027, NUDOCS 9003150485 | |
| Download: ML20033F092 (84) | |
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PHILADELPHIA ELECTRIC COMPANY 4
Peach Bottom Atomic Power Station Unit 3 Docket Number 50-278 l
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REACTOR CONTAINMENT BUILDING INTEGRATED LEAKAGE RATE TEST REPORT t
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Submitted to The United States Nuclear Regulatory Commission Pursuant to Facility Operating License No. DPR-56 GENERAL PHYSICS CORPORATION
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GP R 312027 i
November 20,1989 900315o4s5 900306 PDR ADOCK 05000278 J
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[s TABLE OF CONTENTS l=
1.
INTRODUCTION II.
TEST SYNOPSIS III.
TEST DATA
SUMMARY
A.
- Plant Information B.
Technical Data 1
C.
Type A Test Results D.
Type B and C Test Results E.
Integrated Leakage Rate Measurement System i
F.
Information Retained at Plant IV.
ANALYSIS AND INTERPRETATION V.
APPENDICES A.
Stabilization Summary Data B.
ILRT Summary Data and Graphs C.
Verification Flow Test Summary Data and Graphs L
D.
DTBAT Summary Data and Graphs E.
Description of General Physics ILRT Computer Program -
F.
Failed Sensor Data and Graph G.
Local Leakage Test Summaries L
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. I.
INTRODUCTION The Reactor Containment Building Integrated Leakage Rate " Type A" Test is performed to demonstrate that leakage through the primary reactor containment systems and components penetrating primary containment does not exceed the allowable leakage rate specified in the Plant Technical Specifications.
The purpose of this report is to provide information pertinent to the activities related to the preparation, test performance, and reporting of the Peach Bottom Atomic Power Station, Unit 3, Integrated Leakage Rate Test (ILRT).
The section of this report entitled Test Synopsis "Section II" presents the highlights of activities and events which occurred prior to and during the Test (ILRT).
Test Data Summary "Section III" contains data and results necessary to demonstrate containment atmosphere stabilization, acceptable leakage rate, and successful verification test. In addition, plots provided in Appendices B and C supply a visual history of containment atmospheric conditions beginning with the 27.5 hour5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> test period and ending with the verification test.
a Information in Section IV, Analysis and Interpretation, supplies some of the technical detail associated with the ILRT computer program and its associated hardware as well as the instrumentation used during the ILRT.
i The successful periodic Type A and verification tests were performed according to the requirements of the Peach Bottom Atomic Power Station, Unit 3, Technical Specifications and 10CFR50, Appendix J. The test method utilized is the Absolute Method described in ANSI /ANS 56.81987," Containment System Leakage Testing Requirements." Leakage rate was calculated using formulas from ANSI /ANS 56.8-1981 (Mass Point) during the Type A and verification tests. Type A and verification test duration were conducted according to the criteria of Peach Bottom Atomic Power Station, Unit 3, Plant Technical Specifications.
The test results are reported in accordance with the requirements of 10CFR50, Appendix J, Section V.B.3.
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II.
TEST SYNOPSIS Prior to containment pressurization on October 28, 1989, and subsequent to completing the verification test on October 30,1989, Peach Bottom Atomic Power Station, Unit 3, site test and maintenance personnel were engaged in activities related to containment leakage. Containment leakage was identified thorough the Type B and C localleakage rate testing programs and reduced by repairs to those systems j
and containment components having excessive leakage. The results of the local leakage rate tests are given in Appendix G.
The following discussion highlights some of the activities mentioned above and presents some items that were essential to the successful and timely completion of the Type A test. These items have been presented in a chronological order and are considered to be some of the most significant aethities encountered during test preparation and execution.
i A.
Pre pressurization Activities Pre pressurization aethities included: Completing the majority of Type B and Type C testing; Type A test procedure review; final ILRT instrumentation operability checks; finalILRT computer program checkout; and sensor failure analysis weighting factor calculation checks. A few of these items are discussed below to present pertinent information that impacted on Type A Test aethities.
The Type A test procedure review was conducted to ensure that all references to Plant Technical Specifications,10CFR50, Appendix J, ANSI /ANS 56.8-1987, and the UFSAR were accurate and current. In addition to verifying that the procedure was in compliance with the appropriate guidelines, the valve line up was reviewed to ensure that the containment systems were in as 1
close to post accident arrangement as possible.
FinalILRT instrumentation operability checks were performed to ensure that all instrumentation was operating correctly. An in situ check, as specified in ANSI /ANS 56.81987, Section 4.2.3.1, was conducted to verify that all ILRT instrumentation was working correctly.
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i B.
Containment Pressurization i
Containment pressurization started at 1000 hrs., on October 28,1989, at the rate of approximately 5 psi /hr. Two compressors were running at about 60 psig. Containment test pressure was reached at 1815 hrs. on October 28, 1989.
i C.
Containment Atmosphere Stabilization At 2330 hrs on October 28,1989, all temperature stabilization criteria as specified in ANSI /ANS 56.8 1987, section 5.3.1.6, were satisfied. However, approximately two hours later, there was a large perturbation in the leakage data which, after investigation, was attributed to a momentary unseating of the inboard purge valve.
D.
Test Period Subsequent to meeting temperature and pressure stabilization criteria, leakage rate analysis began at 0400 EST,0500 EDT on October 29,1989.
The ILRT was successfully completed at 0730 hrs on October 30,1989. The maximum allowable leakage rate (L ) for the primary containment is 0.5%
wt./ day of contained air mass at the peak test pressure of 49.1 psig. The measuredleakage rate based on the mass point analysis technique was 0.164%
wt./ day with a mass point leakage reported at the 95% UCL of 0.170%
wt./ day.
1 A successful verification flow test was conducted following the ILRT. It started at 0730 hrs on October 30,1989 and completed at 1145 hrs, on the same day. A leakage equivalent to L,(0.518% wt./ day) was imposed on the existing measured leakage of 0.164% wt./ day. The measured composite leakage rate was 0.6163% wt./ day.
The measured composite leakage rate was within 0.0657% wt./ day of the leakage imposed (L ) plus the measured leakage during the ILRT (Lam), well o
within the acceptable criteria of125% L,(10.125% wt./ day).
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E.
Drywell to Torus Bypass Area Test (DTBAT) j Subsequent to the ILRT and the verification test, the Drywell to Torus Bypass.
Area Test (DTBAT) was conducted. The test started at 1200 hrs on October i
h.1 31, 1989 and was successfully completed after 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />, The maximum i
l acceptable bypass area, as delineated by the PBAPS Technical Specification
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is equivalent to a 1.000 inch I.D. orifice or 0.785 square inch.- The calculated
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bypass area was 0.00365 square inches.
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TEST DATA
SUMMARY
b A.
Plant Information 3
Owner Philadelphia Electric Company
- 1 Plant Peach Bottom Atomic Power Station,
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Unit 3 Location Delta, Pennsylvania Containment Type Metal Vessel Suppression Pool i
NSSS Supplier, Type General Electric, BWR Date Test Completed October 30,1989 g
B.
Technical Data 1
1.
Nominal Containment 293,900 cu. ft.
Net Free Air Volume
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2.
Design Pressure, P 56 psig 3.
Design Temperature, T 281 F 1, '
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Calculated Peak 49.1 psig
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Accident Pressure, P, 5.
Containment ILRT 40135 F Average Temperature Limits 6.
Calculated Peak 283 F Accident Temperature C.
Test Results Type A Test 1.
Test Method Absolute 2.
Data Analysis Technique Mass Point (per ANSI /ANS 56.8 - 1987) 5 s
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3.
Test Pressure 49.1 psig j
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4.
Maximum Allowable 0.500 % wt./ day
!j Leakage Rate, L, Il 5.
75% of L, 0.375 % wt./ day
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6.
Integrated Leakage Rate Test Results
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Mass Point Analysis:
L, a.
Calculated Leakage Rate y
% wt./ day from regression 0.164 p
line, L,,
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Upper 95% Confidence 0.170 Limit
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Integrated Leakage Rate L;:
Test Results TotalTime Analysis l.i -
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Calculated Leakage Rate
% wt./ day from regression 0.156 line, L
=
am x
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Upper 95% Confidence 0.166 Limit
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8.
Verification Test Imposed 4.55 scfm Leakage Rate (0.5 % wt./ day) 9.
Verification Test Results 0.6163 (% wt./ day)
Mass Point Analysis Leakage Rate 6
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10.
Verification Test Limits i
Mass Point Analysis Test Limits (% wt./dav) i f
1)
Upper Limit 0.8082 (Lo + L, + 0.25 L.)
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Lower Limit 0.5582 i
L' (L + L
- 0.25 L,)
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Report Printouts The Report Printouts of the Type A and DTBAT verification test calculations g
are provid:d for the Mass Point Analysis (Appendices B through D). Stabilization data is also provided (Appendix A).
D.
Test Results. Types B and C Tests Refer to Appendix G for a summary of localleakage rate test results since N
the last ILRT performed in 1986.
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E.
Integrated Leakage Rate Measurement System (Model 14636 9325) 1.-
Absolute Pressure (one main plus one backup)
Ran;,e 0-100,000 counts Repeatability 10.001 psia 1
Accuracy 0.015% of reading,10.002% F.S.
Resolution 0.0001 psia Range 0-100 psia Sensitivity 0.001 psia Sensor Type Quartz Manometer Mensor Absolute Digital Pressure Gauge Serial No. 2126 Bourdon Capsule (Type 2) Serial No. 3141 Calibration Date: September 13,1989 7
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Spare: Instrument Serial No. 2127 and Bourdon Capsule Serial No. 3700 Calibration Date: September 13,1989 j
2.
Drybulb Temperature (12 plus 6 spares)
Resistance Temperature Detectors Volumetrics 100 Ohm
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Platinum Resistance Temperature System i
Accuracy:
1 0.1 F 1
Repeatability:
10.01 F Static Resistance:
100 ohms Sensitivity:
< 0.1 F Calibration Date:
August 24,1989 3.
Dewpoint Temperature (6 sensors)
Dewpoint Temperature Probes Chilled Mirror Hydrometers Accuracy:
10.54 F Repeatability:
10.01 F Sensitivity:
< 0.1 F Dew Cell assemblies (calibration date: October 2,1989)
S/N 28-0495 S/N 28 0488 (Moisture. Element S/N 28-0496 S/N 28-0489 No.s ME6566A F)
S/N 28 0487 S/N 28-0490 i
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4.
Verification Flow (1 channel)
Mass Flowmeter - Teledyne Hastings Raydist Model PR 4AJ, Serial No. 462 Accessories:(2) WFM 201 Flow Sensors, S/N 396 and 397 Range:
0 9.9 scfm
, 0.2 scfm Accuracy:
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Calibration Date:
September 25,1989 5.
Overall Instrumentation Selection Guideline (ISG) Value (from ANSI /ANS 56.81981 based on ILRT instrumentation) and an eight hour minimum test duration = 0.032.
6.
Drybulb and Dewpoint Temperature Sensor Volume Fractions - see Procedure retained at jobsite.
F.
Information Retained at Plant 1.
Access control procedures that were established to limit ingress to containment during testing.
2.
A listing of all containment penetrations, including the total number of like penetrations, penetration size, and function.
3.
A listing of normal operating instrumentation used for the leakage rate test.
4.
A system lineup (at time of test), showing required valve positions and status of piping systems.
- 5.
A continuous, sequential log of : vents from initial survey of containment to restoration of all tested systems.
6.
Documentation of instrumentation calibrations and standards. Included with documentation is an error analysis of instrumentation.
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Data to verify temperature stabilization criteria as established by test procedure (Appendix A).
8.
The wc-Idng copy of test procedure that includes signature sign off of procedural steps.
9.
The procedure and all data that verifies completion of penetrations and valve testing (B&C type tests), including as found leak rates, corrective action taken, and final leak rate.
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10.
Computer printouts of Integrated Leakage Rate Test Data and manual i
data accumulation along with summary description of computer program (Appendices B and E).
11.
The Quality Assurance audit plan or checklist that was used to monitor ILRT with proper sign-offs.
12.
A listing of all test exceptions including changes in containment system boundaries instituted by licensee to conclude successful testing.
13.
Description of sensor malfunctions, repairs, and methods used to redistribute volume fractions to operating instrumentation.
1 14.
A review of confidence limits-of test results with accompanying computer printouts where applicable.
15.
Description of method of leakage rate verification of instrument measuring system (superimposed leakage), with calibration information
- on flowmeters along with calculations that were used to measure the verification leakage rate (Appendix E).
16.
Plots presenting ILRT data obtained during the test (Appendices C throughF).
17.
The P&lDs of pertinent systems.
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GP R-312027 GENERAL PHYSICS CORPORATION L-IV.
ANALYSIS AND INTERPRETATION i
Several corrections must be added to the calculated results of the Unit 3 ILRT.
A.
Type B&C Penalties Several corrections must be added for valves / penetrations which were not in i
e their normal post. accident conditiom 1.
RBCC Water 690 SCCM 2.
Chilled Water Valves 10,205 SCCM 3.
Shutdown Cooling Valves 65 SCCM 4.
ILRT Test Valves
- 30 SCCM 5.
Drywell Equipment Drain Sump 1645 SCCM 6.
Drywell Floor Drain 306 SCCM 7.
C & D CAD Sample Inlet 200 SCCM 8.
N2 Makeup to Contaiment 10 SCCM Total 13,151 SCCM which equates to an addition of 0.0471% wt./ day r
B.
Volume Change Corrections 1.
During the test, Reactor Vessel water level, Torus water level, Drywell Equipment Drain, and Drywell Floor Drain sump levels were continuously monitored and experienced level changes. The totallevel changes resulted in a decrease in the containment net free volume equivalent to an addition to the ILRT calculated leakage rate of 0.0057% wt./ day.
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HCU Accumulator In leakage Corrections Readings of HCU Accumulator pressures were recorded at the start of the test and the end of test. The result was an addition to the ILRT calculated leakage of 0.0067% wt./ day to account for HCU accumulator in leakage.
D.
Reported ILRT Results The results of the Unit 3 ILRT to be reported including all corrections are:
1 1.
Measured leakage Rate at 95% UCL based on mass point analysis 0.1699% wt./ day 2.
Final level corrections 0.0057% wt./ day per Appendix Y of ST-12.5 3.
HCU Accumulator in leakage corrections per Appendix P of ST-12.5 0.0067% wt./ day
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Corrections for valves not in Accident Positions from Appendix L of ST-12.5 0.0471% wt./ day 5.
Total leakage rate (Total of items 1 through 5) 0.2294% wt./ day l
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APPENDIX A STABILIZATION SUhBIARY DATA 3
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63.711" I
5 W
W 1839/ 391 TIME 2315/ 391 h
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GTADILIZATION ANSISS.8 i
L 11MC TCMP 50.0 53.8 PRESS 56.0 1 HR 4 HR dP i
F/HR F/HR PSI /HR S.00 74.43
-0.29
-0.40 63.70
.0091 4.75 74.40
-0.33
-0.42 63.71
.0100 4.50 74.56
-0.34
-0.45 63.7R
.0107 4.2S 74.61
-0.33
-0.49 63.73
.0116 4.00 74.72
-0.36
-0.56 63.74
.0120 l
3.75 74.81
-0.34 0.00
'63.76
.0119 4
3.50 74.90
-0.36 0.00 63.77
.0126 3.25 74.96
-0.40 0.00 63.78
.0135 i
3.00 75.07
-0.41 0.00 63.79
.0114 L
2.75 75.14
-0.47 0.00 63.61
.0168 2.50 75.26
-0.48 0.00 63.82
.0134 g.
2.25-75.36
-0.51 0.00 63.84
.0155 2.00 75.49
-0.53 0.00 63.85
.0166 10 1.75 75.61
-0.56 0.00 63.87
.0170 9
libo 75.74
-0.63 0.00 63.88
.0178 1.25' 75.87
-0.70 0.00 63.90
.0004
(
1.00 76.02
-0.93 0.00 63.92
.0212 l
O.75 76.17 0.00 0.00 63.94 0.0000 0.50 76.37 0.00 0.00 63.97 0.0000 0.25 76.57 0.00 0.00 64.00 0.0000 0.00 76.95 0.00 0.00 64.05 0.0000 t
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DN-TOP-1'STABLIZATION CRITERIA:
TIME:
1EMP DN-
'FN g
d T.
dT2
- 5. 00 ~
74.4290
-0.3639
-0.3226' 4.75 74.4731
-0.3338
-0.3324 4.50 74.5564
-0.3793
-0.3509 4.25 74.6070
-0.3907
-0.3774 4;00.
74.7180
-0.4269
-0.3844 3.75 74.8061
-0.4496
-0.4020 3.50
'74.'7010
-0.4704
-0.4178 U.25 74.9569
-0.4927
-0.4558
'I
-3.00 75.0742
-0.5349
-0.4737 2.75 75.1429
-0.5582
-0.5141 2.50 75.2583
-O,6398
-0.5556 2.25 75.3619
-0.6969
-0.6046 2.00 75.4868
-0.9833
-0.7340 1.75 75.6100 0.0000 0.0000 l
1.50 75.7365 0.0000 0.0000 1.25 75.8685 0.0000 0.0000 1.00 76.0017 0.0000 0.0000 O.75 76.1710 0.0000 0.0000 0.50-76.3696 0.0000 0.0000 l
O.25 76.5712
- 0. OO bo 0.0000 0.00 76.9548 0.0000 0.0000 i.
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I AVG. DATA VALUES UNIT H 3 DATE TIME.
T(I)-.
P(I)
DT(I)
VP(I)
MASG(I) 301 0.00 76.95 64.05 65.16 0.307 94678 301 0.25 76.57 64.00 65.03 0.306 94677 301 0.50 76.37 63.97 64.78 0.303 94669
-301 0.75
-76.17 63.94 64.59 0.301 94665 301 1.00 76.00 63.92 64.48 0.300 94660 301 1.25 75.87 63.90 64.38 0.299 94657 301 1.50 75.74 63.88 64.24 0.297 94654 301 1.75 75.61 63.87 64.11 0.296 94651 301 2.00 75.49 63.85 64.04 0.295 94648 301 2.25 75.36 63.84 63.96 0.295 94647 301 2.50 75.26 63.82 63.88 0.294 94646 301 2.75 75.14 63.81 63.82 0.293 94641 301 3.00 75.07 63.79 63.74 0.292 94637 301 3.25 74.96 63.78 63.67 0.292 94637 301 3.50 74.90 63.77 63.60 0.291 94628 301 3.75 74.81 63.76 63.47 0.290 94628 301 4.00-74.72 63.74 63.45 0.289 94625 301 4.25 74.61 63.73 63.39 0.289 94628 301 4.50 74.56 63.72 63.34 0.288 94621 301 4.75 74.48 63.71 63.24 0.287 94619 301 5.00 74.43 63.70 63.24 0.287 94615 i
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i APPENDIX B ILRT SUf, DIARY DATA AND GRAPHS l-
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TOTAL TIME UNIT H<3 g
[TTLM T:
DATE TIME LMCALC SL LAM-L9 I
302' O.00'-
0.0000 0.0000 0.0000 0.0000
- 0. O(
302 0.25 0.6002 0.0000 0.0000 0.0000
- 0. O(.
302 0.50 0.3576.
0.0000 0.0000 0.3565
- 1. S! '
302 0.75 0.2708 0.2449 0.8612 0.2552
- 0. 5e,
300 1.00
'O.4360 0.3293 1.0573 0.3697
- 0. 56 >
302.
1.25 0.3889 0.3419 0.0299 0.3791 0;49 b
302 1.50 0.3104 0.3090 0.6764 0.3332 0.42 302 1.75 0.2951 0.2843 0.5857 0.3035 0.37-300 2.00 0.3046 0.2742 0.5370 0.2930 0.35-302 2.25 0.2738 0.2569 0.4903 0.2743 0.32 1 302 2.50 0.3000 0.2557 0.4731 0.2763 0.31
'302 2.75 0.2858 0.2504 0.4530 0.2718-0.30-302 3.00 0.3157 0.2559 0.4521 0.2812 0.3L 302 3.25 0.2272 0.2362 0.4198 0.2556 0.29 302
-3.50 0.2888 0.2374 0.4153 0.2596 0.29 302 3.75 0.2761 0.2357 0.4069 0.2590 0.28-300 4.00 0.3129 0.2430 0.4136 0.2701 0.29 302 4.25 0.2881 0.2438 0.4096 0.2713 0.29 302-4.50 0.2818 0.2435 0.4044 0.2707 0.29:
302 4.75-O.3000 0.2470 0.4051 0.2754 0.29 302 5.00 0.2887 0.2479 0.4024 0.2759 0.29 4
302 5.25 0.2681 0.2452 0.3950 0.2717 0.20 300 5.50 0.2847 0.2459 0.3926 0.2723 0.28 302 5.75 0.2899 0.2475 0.3915 0.2741 0.20 302 6.00 0.2915 0.2492 0.3909 0.0762 0.2G 302 6.25 0.3029 0.2525 0.3927 0.2802 0.29
1-TOTAL TIME-UNIT H 3 t
s DATE TIME TTLM LMCALC GL LAM-LV e
302 6.50 0.3040 0.2556 0.3942 0.2938 0.2v 302 6.75 0.3176 0.0604 0.3902 0.0897 0.30 302 7.00 0.3065 0.2631 0.3992 0.2926 0.30 1 -
302 7.25 0.3062 0.2655 0.3999 0.2946 0.30 302 7.50 0.3055 0.2676 0.4002 0.2962 0.30 302 7.75 0.2907 0.2677
_O.3979 0.2951 0.30 302 8.00 0.2947 0.2683 0.3964 0.2949 0.30 302 8.25 0.2884 0.2682 0.3941 0.2937 0.30 302 8.50 0.2986 0.2693 0.3934 0.2942 0.30-302 8.75 0.2893 0.2692 0.3914 0.2932-0.30 302 9.00 0.2862 0.2689 0.3892 0.2919 0.29' 302 9.25 0.2764 0.2676 0.3860 0.2893 0.29 302 9.50 0.2921 0.2681 0.3848 0.2893 0.29, 302 9.75 0.2794 0.2673 0.3823 0.2875 0.29i 302 10.00 0.2692 0.2656-0.3788 0.2845 0.29-302 10.25 0.2674 0.2638-0.3755 0.0817
. O. 28i 302 10.50 0.2636.
O.2619 0.3700 0.2787 0.28.
300 10.75 0.2523 0.2592 0.3677 0.2745 0.28-302 11.00 0.2569 0.2571 0.3641 0.2714 0.28+
302 11.25 0.2609 0.255b O.3612 0.2692 0.27 302 11.50 0.2456 0.2528 0.3571 0.2652 0.27-302 11.75 0.2491 0.2506 0.3535 0.2622 0.27.
302 12.00 0.2477 0.2484 0.3501 0.2592 0.26i 302 12.25 0.2504 0.2466 0.3471 0.2569 0.26.
'302 12.50 0.2486 0.2448 0.3442 0.2547 0.26 302 12.75 0.2408 0.2426 0.3408 0.2517 0.26s
TOTAL--TIME UNIT 14 3 s
DATE TIME TTLM LMCALC SL LAM L'.
. - - - - - - - - - - - - - - - - - - - - - - - - -.. - ~ ~ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -..
302
'13.00-0.2460 0.2409 0.3381
-0.2497-O 2t 302 13.25 0.2324 0.2384 0.3345 0.2464 0.2t 302 13.50 0.2435 0.2368 0.3319 0.2446 0.2t
-302
'13.75 0.2358 0.2348-0.3289 0.2423 0.21
-302 14.00 0.2300 0.2326 0.3257 0.2395 0.24 302 14.25 0.2269 0.2303~
0.3224 0.2367 0.24 302 114.50 0.2296 0.2283 0.3195 0.2345 0.24 302
-14.75 0.2208 0.2258 0.3162 0.2315
.O.24 302 15.00 0.2198 0.2235 O.3130 0.2288 0.23 302 15.25-0.2232 0.2215 0.3102 0.2265 0.23-
-302 15.50 0.2248 0.2198 0.3076 0.2247 0.23-302 15.75 0.2136 0.2174 0.3045 O'.2221 0.23 302 16.00 0.2136 0.2152 0.3016 O.2196 0.22:
302 16.25-0.2187 0.2135 0.2991' O.2178 0.22 302
.16.50 0.2175 0.2117 0.2966 0.2160 0.22 302 16.75 0.2055 0.2094 0.2936 0.2135 0.22 302=
17.00_
O.2123 0.2076 0.2911 0.2116 0.22 302-17.25 0.2074.
O.2057 0.2885 0.2095 0.21 302 17.50' O.2005 0.2035 0.2857 0.2073 0.21 302 17.75 0.2055 0.0017 0.2832 0.2053 0.21-302 18.00 0.2111 0.2002 0.2811 0.2041 0.21 302 18.25' O.2073 0.1987 0.2790 0.2026 0.21 302 18.50 0.0038 0.1970 0.2767 0.2010 0.00 302 18.75 0.2142 0.1960 0.2752 0.2003 0.20:
303 19.00 0.2069 0.1946 0.2734 0.1991 0.20 303 19.25 0.2008 0.1934 0.2717 0.1981 0.20 b
-ow x
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TOTAL ~TIPlE UNIT H 3--
'l
~DATE TIPlE TTLM LPICALC -
SL LArt t J.
303 19.50 0.2054 0.1922 0.2699 0.1970 0. 2<,.
303 19.75 0.2019 0.1908 0.26G0 0.1957.
O. 28 303-20.00 0.1997 0.1893 0.2661 0.1942 RO.2c 303 20.25 0.1929 0.1877-0.2639 0.1925 0. 21.
.303 20.50 0.1957 0.1862-0.2619 0.1911 0.19-303 20.75 0.1957 0.1848 0.2601 0.1898 0.19 303 21.00_-
0.1890 0.1831 0.2580 0.1881 0.19:
303 21.25
-0.1950 0.1819 0.2563 0.1870 0.19 303 21.50 0.1964 0.1807 0.2547 0.1860 0.19 303 21.75 0.1907 0.1793 0.2529 0.1846 0.19 303 22.00 0.1930 0.1781 0.2513 0.1836 0.19 303 22.25 0.1897 0.1769 0.2497 0.1825 0.18 303 22.50 0.1906 0.1757 0.2481 0.1815 0.1,8 303
-22.75 0.1921 0.1746 0.2467 0.1806 0.18 303 23.00 0.1885 0.1734 0.2452 0.1795 0.18 303 23.25 0.1907 0.1724 0.2439 0.1786 0.18 303' 23.50 0.1922 0.1715 0.2427 0.1780 0.18 303 23,75 0.1858 0.1704 0.2412' O.1770 0.18 303 24.00 0.1856 0.1693 0.1810 0.1760 0.16 303 24.25 0.1885 0.1683 0.1799 0.1753 0.10-303 24.50 0.1813 0.1672 0.1787 0.1742' 0.10 303 24.75 0.1810 0.1660 0.1774 0.1732 0.17
- 303 25.00 0.1814 0.1649 0.1762 0.1722 0.17 303 25.25 0.1784 0.1638 0.1750 0.1712 0.L7-303 25.50 0.1814 0.1628 0.1739 0.1704 0.17 303 25.75 0.1806 0.1618 0.1728 0.1695 0.17 t
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c AVG. DATA' VALUES UNIT li 3 a:,
c, D, ATE
' TIME T(I).
P(I)
DT(I)
VP(I)
MASS (I) t
-302 0.00 73.41~
63.52 62.82 0.283 94531 302 0.25 73.40 63.52 62.80 0.283 94525 302 0.50 73.35 63.51 62.73 0.282 94524 302-0.75 73.30 63.51 62.71 0.232 94523 302 1.00 73'.30 63.50 62.71 0.282 94514 302 1.25 73.26 63.49 62.66 0.2G1:
94512 302 1.50 73.21 63.49 62.66 0.201 94513 302 1.75 73.17 63.48 62.62 0.283 94511 302 2.00 73.15 63.48
<62.63 0.281 94507 302 2.25 73.10 63.47 62.62 0.281 94507 302 2.50 73.09 63.47 62.60 0.001 94501 302 2.75 73.05 63.46 62.55 0.280-94500 302 3.00 73.04 63.46 62.54 0.280 94494 302 3.25 72.96 63.45 62.48 0.280
'"4502 302 3.50 72.98 63.45 62.53 0.280 94491 302 3.75 72.94 63.44 62.58 0.281 94490 302 4.00 72.95 63.44 62.52 0.280 94482 302 4.25 72.90 63.43 62.48 0.280 94483 300 4.50 72.87 63.43 62.50 0.280 94481 302 4.75 72.86 63.42 62.49-0.280 94475.
302 5.00 72.82 63.42 62.45 0.279 94474 302 5.25 72.77 63.41 62.45 -
0.279 94476 302
.5.50 72.77 63.41 62.45 0.279 94469 302 5.75 72.74 63.40 62.47 0.280-94465 302-6.00 72.73 63.40 62.45 0.279 94462 302
-6.25 72.71 63.39 62.45 0.279 94456 302 6.50 72.69 63.39 62.44 0.279 94453 302 6.75 72.69 63.38 62.45 0.279 94447 302 7.00 72.67 63.38 62.42 0.279 94447 302.
7.25 72.65 63.37 62.43 0.279 94444 302 7.50 72.63 63.37 62.43 0.279 94441 302 7.75,72.58 63.37 62.40 0.279-94442 302 8.00 72.58 63.36
-62.37 0.279' 94438 302 8.25 72.56' 63.36 62.40-0.279 94437
-302 8.50 72.56 63.36 62.40 0.279 94431 302 8.75 72.52 63.35 62.38 0.279 94431 302 9.00 72.51 63.35 62.35 0.278 94430 302-9.25 72.48 63.35 62.38 0.279 94430
'302 9.50 72.49 63.34 62.37
-0.279 94422 302 9.75 72.46 63.34 62.30 0.278 94424 302-10.00
'72.45 63.34 62.34 0.278 94425 302 10.25 72.44 63.34 62.36 0.278 94423 302.
10.50 72.43 63.33 62.39 0.279 94422 302 10.75 72.41 63.33 62.39 0.279 94424 302 11.00 72.41 63.33 62.42 0.279 94420 302 11.25 72.42 63.33 62.39 0.279 94415 302 11.50 72.37 63.33 62.38 0.279 94420 E
302.
11.75 72.38 63.32 62.36 0.278 94416 302 12.00 72.36 63.32 62.41 0.279 94414 302 12.25 72.37 63.32 62.38 0.279 94410 302 12.50 72.36 63.32 62.37 0.079 94409
4:
AVO. DATA VALUES
. UNIT H 3' ls DATE
. TIME T(I)
P(I)
DT(I)
VP(I)
MASS
_L_______-_______________________________________________________(I)__
302 12.75 72.32 63.31 62.39 0.279 94410 302 13.00 72.33 63.31 62.41 0.279 9440S 302 13.25 72.30 63.31 62.35 0.278 94410 302 13.50 72.32 63.31 62.43 0.279 94402 302 13.70=
72.29 63.30 62.38 0.279 94403 302 14.00 72.27 63.30 62.36 0.278 94404 302 14.25 72.26 63.30 62.32 0.278 94404 302 14.50 72.26 63.30 62.37 0.279 94400 302 14.75 72.23 63.30 62.33 0.278 94403 302 13.00' 72.21 63.29 62.28 0.278 94401 302 15.25.
72.21 63.29 62.35 0.278 94397 302 15.50 72.22 63.29 62.33 0.278 94394 302 13.75 72.18 63.29 62.29 0.278 94399 302 16.00 72.17 63.29 62.32 0.278 94396 302
-16.25 72.18 63.28 62.31 0.278 94391 302 16.50
.72.17 63.28 62.30 0.278 94390 302 16.75 72.12 63.28 62.32 0.278 94395 302 17.00-72.13 63.28 62.33 0.278 94309 302 17.25 72.11 63.27 62.36 0.278 94390 302 17.50 72.08 63.27 62.31 0.278 94391 302' 17.75 72.09 63.27 62.28 0.278 94387 302 18.00 72.09 63.27 62.28 0.278 94381 302 18.25 72.06 63.26 62.30 0.278 94382 302 18.50 72.04 63.26 62.27 0.278 "94383 302 18.73'
'72.00 63.26 62.24 0.277
~94373 303 19.00 72.03 63.26 62.20 0.277 94376 303 19.25 72.03 63.2S 62.27 0.278
,94373 303 19.50 72.02 63.25 62.22 0.277 94373 303 19.75 71.99 63.25 62.19 0.277 94374 303 20.00 71.97 63.25 62.27 0.278 94374 303-20.25 71.94 63.25 62.17 0.277 94377 303-20.50 71.94 63.24 62.15 0.276 94373 303 20.73 71.94 63.24 62.15 0.276 94371 303 21.00 71.89 63.24 62.20 0.277 94375 303 21.25 71.91 63.24-62.21 0.277 94368 303 21.50 71.92 63.23 62.14 0.276 94365 303!
=21.75 71.89 63.23 62.19 0.277 94368 303 22.00 71.91 63.23 62.20 0.277 94364 303-22.25 71.89 63.23 62.20 0.277 94365 303 22.50 71.88 63.23 62.23 0.277 94362 303 22.75 71.89 63.23 62.13 0.276 94359 303 23.00 71.85 63.22 62.2S 0.277 94360' 303-23.25 71.87 63.22 62.18 0.277 94356 303 23.50 71.86 63.22 62.19 0.277 94353 303 23.75 71.82 63.22 62.12 0.276 94357 303 24.00 71.81 63.22 62.21 0.277 94356 303 24.25 71.82 63.21 62.19 0.277 94351 303 24.50 71.78 63.21 62.15 0.276 94356 303 24.75 71.78 63.21 62.15 0.276 94355 303 25.00 71.78 63.21 62.19 0.277 94352 l
l
AVG. DATA VALUES =
- UNIT _ H
- 3 D, ATE l
'TIrlE, T(I)
P(I)-
DT(I).
VP(I)
PIASS(I) l
. f303
- 23.25 71.76 63.21 62.21 O.277 94354
-303' 25.50
'71.76 63.21
'62.19 0.277-94349 303-23.75
~71.76 63.20
'62.19 0.277 94348 303 26.00~
71.74 63.20-62.21 0.277 94346
-303' 26.25-71.73' 63.20-62.20-0.277 94345 303.
26.50 71.73-63.20 62.17 0.277 94343 303 26.75 71.70 63.20-62.15 0.276 94345 303_
27.00' 71.68 63.19 62.19; O.277 94345 303 27.25 71.70 63.19 62.16 0.277 94340 303 27.50 71.~68 63.19 62.13 0.276 94336
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AVG.. DATA VALUES UNIT C 0
.7 DATE.
TIME T(I)
P(I)
DT(I)
VP(I)
MASSFI) 300 0.00 70.41 60.52 62.82 0.28; C4501
<002' O.25 73.40 63.50 62.80 0.28; 94525 MFQ2 0.50-73.05 63.51 62.70 0.282
- 94524 300 0.75 73.30 63.51 62.71 0.282 9452 502 1.00 73.00 63.50 62.71 0.282 44514 2002 1.25 73.26 63.49 62.66 0.281 94512 302 1.50-70.21 60.49 62.66 0.281 94510 002 1.75 73.17 60.48 62.62 0.281 94511 302 2.00 70.15 63.48 62.63 0.281 94507 002 2.25 73.10 63.47 62.62 0.281 94507 302 2.50 73.09 63.47 62.60 0.281 94501
' ~002 2.75 70.05 63.46 62.55 0.280 94500 002 3.00 75.04 63.46 62.54 0.280' 94494 002 3.25 L72.96 63.45 62.48 0.280 94502 000 0.50-72.98 63.45 62.50 0.280 94491 302 0.75 72.94 63.44 62.58 0.281 94490 002 4.00 72.95 63.44 62.50 0.280 94482 302 4.25 72.90 63.40 62.48 0.280 94480
~302-4.50 70.87 63.43 62.50 0.280 94481
=302 4.75 72.86 63.42 62.49 0.280 94475 302 5.00 72.82 63.42 62.45 0.279 94474
- 302 5.25 72.77 63.41 62.45 0.279 94476 302.
5.50 72.77 63.41 62.45 0.279 94469
.302 5.75 72.74 63.40 62.47 0.200 94465 302 6.00 72.73 63.40 62.45 0.279 94462 302 6.25 72.71 63.39 62.45 0.279 94456 302 6.50 72.69 63.39 62.44 0.279 94453 302 6.75 72.69 63.38 62.45 0.279 94447 302 7.00 72.67 63.38 62.42 0.279 94447 302 7.25 72.65 63.37 62.43 0.279 94444 302 7.50 72.63 63.37 62.43 0.279=
94441-302 7.75 72.58 63.37 62.40 0.279 94442 302 8.00 72.58 63.36 62.07 0.279 94438
'302 8.25
.72.56 63.06 62.40 0.279 94407 302 8.50 72.56 63.36 62.40 0.279 94431 302 8.75 72.52 63.35 62.38 0.279 94431
'002 9.00 72.51 63.35 62.35 0.278 94400 000 9.25 72.48 63.05 62.08 0.279 94400 302 9.50 72.49 63.34 62.07 0.279 94422 302 9.75 72.46 63.34 62.30 0.278 94424 302 10.00 72.45 63.34 62.04 0.278 94425 302 10.25 72.44 63.34 62.36 0.278 94420 002 10.50 72.43 63.33 62.39 0.279 94422 002 10.75 72.41 63.33 62.09 0.279 94424
, 302 11.00 72.41 63.33 62.42 0.279 94420 002_
11.25 72.42 63.33 62.09 0.279 94415 302 11.50 72.37 63.33 62.38 0.279 94420 00%
11.75 72.38 63.02 62.06 0.278 94416 002 12.00 72.06 63.02 62.41 0.279 94414 000 12.25 72.37 63.32 62.38 0.279 94410 L
002 12.50 72.06 63.32 62.07 0.279 94409 m
=
m
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-AVG. DATA VALUES UNIT O 3
'DSTE TIME.
.T(I)
P(!)
DT(I)
VP('.)
MA58(I)
E000 10.75 70.'02 63.01 62.39 0.079 94410 000 13.00-72.00 63.01 60.41 0.079 94405 000 13.05 70.00 63.31 60.05 0.278 94410 000-10.50' 70.32 6 ~..
t.
62.40 0.279 94400
'302 30.75 70.09 63.00 62.38 0.279 94400 302 14.00 70.27 60.00 60.06 0.078 94404
--000 14.25 72.26
-63.00 62.!
0.078 94404 300 14.50 70.06 63.~0 62.07 0.279 94400 300 14.75 72.00 63.00 62.30 0.278 94403 300 15.00 70.01 63.09 62.03 0.278 94401 000 15.25 72.21 63.09 62.05 0.078 94097 300 15.50 72.20 63.09 62.03 0.078 94094 300 15.75 72.18 63.29 62.29 0.278 94399 302 16.00 72.17 63.09 62.00 0.078 94096 002 16.25 70.18 63.28 60.31 0.278 94~91
~000 16.50 72.17 63.08 62.35 0.278 94390 300 16.75 72.12 63.08 62.00 0.278 94395 300-17.00 70.13 63.28 62.00 0.278 94089 002 17.05 72.11 63.27 62.36 0.278 94390 300 17.50 72.08 63.07 62.01 0.278 94391 302 17.75 72.09 63.07 62.28 0.278 94387
'l
- 002 18.00 72.09 63.07 62.28 0.078 94381 i
'302 18.25 72.06 63.06 62.30 0.078 94380 300 18.50.
72.04 63.06 62.27 0.278 94380 j
300 18.75 72.08 63.26 62.24 0.277 94373 303 19.00 72.03 63.26 62.00 0.277 94376 303 19.25 70.03 60.25 62.27 0.278 94073 303 19.50 72.02 60.25 62.22 0.277 94373
.300 19.75
'71.99 63.05 62.19 0.277 94374 303-20.00 71.97 63.25 62.27 0.278 94374 i
t
~303 20.25 71.94 63.25 62.17 0.277 94377
~003 20.50 71.94 ~
63.24 62.15 0.276 94373 L303 20.75-71.94 63.24 62.15 0.276 94371
.]
303 01.00 71.89 63.04 62.20 0.077-94~75
'i 500 21.25 71.91 63.24 62.01 0.277 94068
'l
- 303-21.50 71.92 63.03 62.14 0.076 94365 000L 21.75 71.89 63.23 62.19 0.277 94368 i
003 20.00 71.91 63.23 62.20 0.277 94064 i
~0' 20.25 71.89 63.03 62.00 0.277 94565 303 22.50 71.88 63.20 62.20 0.077 94~60
~303-22.75 71.89 63.03 62.15 0.276 94059
.003 23.00 71.85 63.02 62.25 0.277 94360 003 23.25 71.87 63.00 62.18 0.277 94356 T300 00.50
'71.86 63.22 62,19 0.277 94350 000 20.75 71.82 60.22 60.10 0.076 94357 00~
24.00
-71.81 63.02 62.21 0.277 94356
-003 24.25 71.82 63.21 62.19 0.277 94351.
303 24.50 71.78 63.21 62.15 0.076 94356 000-24.75 71.78 63.21 60.15 0.076 94355 003 25.00 71.78 63.01 62.19 0.277 94050 i
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'" [FLEASE1CELECTTTHE OPTION
?YPI-WISHJTO USE:
TEST DATA' T
1:-
R-MANUAL DATA ENTRY.
- .OF DATA POINTS-=
18:
1 MODE DURATI'N,(IN HOURS)-=
'4. 2 5 -
-2< ec PARAMETER' GRAPHS O
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. TOT TIME' MEASURED LEAK = 0.6034 4r
=:-TREND' ANALYSIS TOT: TIME : CALCULATED LEAK =--0.6399 M
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-c REPRINT ~ CURRENT DATA PT MASS PT LEAK = 0.6163
- 6
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.5184578 PASS WORD MENU ~
' TOT TIME' UPPER LIMIT = 0.7997' P-
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' TOT TIME LOWER ~ LIMIT = 0.5497
LOWER LIMIT = 0.5582 9
MASS =
94235.1 TOT TIME VERIFICATION CRITERIA HAS BEEN MET-MASS PT VERIFICATION CRITERIA-HAS BEEN MET 4
MASS POINT DATE
-TIME CALC. LEAK RATE 303.
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- 303' 1.00 0.4583 0.4942 1.0831 0.4936 0.6773 E
- 303 1.25 0.5300 0.5284 0.8995 0.5282 0.6452 303 1.50 0.6019 0.5824 0.8658 0.5867 0.6904 1303 1.75 0.5522 0.5889 0.8310 0.5833 0.6579
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_PLEASE SELECT THE OPTION YOU WISH'TO USE:
TEST DATA 11 -
MANUAL DATA. ENTRY
- OF DATA POINTS =
18 2'
PARAMETER GRAPHS MODE DURATION (IN HOURS) 4.25
=
3 SENSOR PLOTS TOT TIME MEASURED LEAK = 0.6034 4
TREND ANALYSIS TOT TIME CALCULATED LEAK = 0.6399
'S REPRINT CURRENT DATA PT MASS PT LEAK = 0.6163 6
SENSOR' DIFFERENTIALS IMPOSED LEAK =
.5184578
-P.
PASS WORD MENU TOT TIME UPPER LIMIT = 0.7997 TOT TIME LOWER LIMIT = 0.5497
' SELECTED OPTION =
MASS PT UPPER LIMIT = 0.8082 MASS PT LOWER LIMIT = 0.55S2 MASS =
94275.1 TOT TIME VERIFICATION CRITERIA HAS BEEN MET MASS PT VERIFICATION CRITERIA HAS BEEN MET
I AVG, DATA-VALUES UNIT:# 3 l
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-DATE TIME T(I):
P(I)
DT(!)
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MASS (I)
- i--
303 0.00 71.68 63.19 62.13 0.276 94336 48 303 0.25 71.67 63.18 62.13 0.276 94332 j-303 0.50 71.64 63.18 62.08 0.276 94330 4-303 0.75 71.64 63.17 62.13 0.276 94319 ti '
303'
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303-1.50 71.62 63.16 62.08 0.276 94300 3
303 1.75-71.59 63.15 62.08 0.276 94298
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303 3.00 71.55 63.12 62.04 0.275 94265' 2
303 3.25 71.55 63.12 62.02 0.275 94260 303 3.50 71.54 63.12 62.07 0.276 94253 y
303 3.75 71.53 63.11 62.07 0.276 94247 4.
303 4.00 71.51 63.11 62.01 0.275 94244 303 4.25 71.51 63.10 62.07 0.276 94235
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SUMMARY
DATA AND GRAPHS 9
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SYPASS, MODE PLEASE SELECT THE OPTION YOU WISH TO USE:
TEST DATA l
1 MANUAL DATA ENTRY
- OF DATA POINTS =
12 2
PARAMETER GRAPHS
' MODE DURATION (IN HOURS) 1
=
3 SENSOR PLOTE TORUS VOLUME
=
127700 4
CHANGE TORUS VOLUME TORUS PRESSURE
= 14.931 5
REPRINT CURRENT DATA PT DRY WELL PRESSURE 16.473
=
[
CALCULATED ORIFICE SIZE (SQ IN) 0.00365 l
=
DRYWILL TO TORUS BYPASS CRITERIA IS MET P
PASS WORD MENU SELECTED OPTION =
ORIFICE SIZE PLOT DATE TIME ORIFICE S!ZE (IN) 304 0.00 0.000 304 0.17 0.000 304 0.25 0.006 304 0.33 0.004 304 0.42 0.003 304 0.50 0.003 304 0.58 0.003 304 0.67 0.003 304 0.75 0.005 304 0.83 0.004 304 0.92 0.003 304
. 00 0.004 l
i PRESS # OF PAGE DESIRED 1,2,3,4 OR OTHER KEY FOR MAIN MENU l
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PLEAE SELECT THE OPTION I
YOU WISH TO USE:
TEST DATA MANUAL DATA ENTRY
- OF DATA POINTS =
12 1
PARAMETER GRAPHS MODE DURATION (IN HOURS)
=1 2
3 SENSOR PLOTS TORUS VOLUME
=
127700 CHANGE TORUS VOLUME TORUS PRESSURE
= 14.831 4
REPRINT CURRENT DATA PT DRY WELL PRESSURE
= 16.473 l
5 CALCULATED ORIFICE SIZE (50 IN) = 0.00365 l
i DRYWELL TO TORUS BYPASS CRITERIA IS MET l
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304 0.42 0.003 i
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}O PRESS H OF PAGE DESIRED:1,2,3,4 OR OTHER KEY FOR MAIN MENU AVG. PRESSURE DATE TIME PSP PDW 304-0.00 14.803 16.468 304 0.17 14.809 16.467 304
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304 0.33 76.115 50.851
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304 0.42 76.179 50.737 j
304 0.50 76.229 50.718 304 0.58 76.275 50.595 l
304 0.67 76.313 50.473 i
304 0.75 76.350 50.477 304 0.83 76.388 50.429 304 0.92 76.425 50.345 304 1.00 76.449 50.352 i
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PRESS # OF PAGE DESIRED:1,2,3,4 OR OTHER KEY FOR MAIN MENU AVG. VAPOR PRESS DATE TIME VPSP VPDW 304 0.00 0.441 0.186 304 0.17 0.444 0.194 304 0.25 0.445 0.194 304 0.33 0.446 0.184 304 0.42 0.447 0.183 304 0.50 0.448 0.183 304 0.58 0.448 0.192 304 0.67 0.449 0.181 304 0.75 0.449 0.181 304 0.83 0.450 0.191 304 0.92 0.451 0.180
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304 0.00 14.803 16.408 304 0.17 14.C09 16.467 30.4 0.25 14.813 16.468 304 0.33 14.815 16.468 304 0.42 14.817 16.469 l
304 0.50 14.019 16.469 304 0.58 14.821 16.470 304 0.67 14.823 16.470 I
304 0.75 14.829 16.470 304 0.83 14.829 16.471 304 0.92 14.928 16.472 304 1.00 14.831 16.473 i
PRESS # OF PAGE DESIRED:1,2,3,4 OR OTHER KEY FOR MAIN MENU AVG., TEMPERATURE l
DATE TIME TSP TDW 304 0.00 75.498 71.402
+
304 0.17 75.579 71.524 304 0.25 75.639 71.584 304 0.33 75.691 71.605 304 0.42 75.729 71.632 304 0.50 75.763 71.665 304 0.58 75.796 71.603 304 0.67 75.922 71.738 304 0.75 75.862 71.770 304 0.93 75.899 71.774 304 0.92 75.917 71.828 304 1.00 75.942 71.936 s
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304 0.42 9539.1 13905.2 304 0,50 9540.0 13904.4 3041 0.58 9540.2-13904.7 i,
1304 0.67 9541.3 13903.9 v
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i APPENDIX E DESCRIPTION OF GENERAL PHYSICS ILRT COMPUTER PROGRAM
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GP,R 312027 GENERAL PHYSICS CORPORATION DESCRIPTION OF GENERAL PHYSICS ILRT COMPUTER PROGRAM 1
The General Physics ILRT team is equipped with two fully operational IBM compatible
~
microcomputers for use by General Physics during ILRT's, Drywell Bypass Tests and "zero-pressure tests" for on site data reduction and analysis. The computer software and hardware is capable of interfacing with the plant's Volumetrics Data Acquisition System and most other standard data acquisition systems.
Two computers are brought on site for 100% redundancy, as each computer and its software is capable of independently performing the ILRT. The General Physics ILRT Data Management Software is also capable of accepting manualinput of raw sensor data and performing all required sensor data conversions if the client's data logger should cease to function. Each computer will be equipped with back up discs in the unlikely event i a disc " crash." Also, the program is runnable on any IBM " compatible" PC with 512K memory and two disc drives.
The General Physics ILRT Data Management Computer Program is written in IBM's BASICA. BASICA is a high level programming language which combines programming ease with user oriented command functions to create an easy to use and understand program. In order to increase speed of operation the program was then compiled into an executable command file. Compiling was accomplished using the IBM Basic Compiler. In addition to execution speed, this had the added benefit of making the program more secure as compiled programs cannot be edited or changed.
The program itself is designed to be a menu driven program consisting of seven seperate, menu driven operating modes. These are the:
1.
Installation Mode 2.
Pre Test Mode 3.
Pressurization Mode 4.
Stabilization Mode 5.
Test Mode 6.
Verification Mode 7.
Depressurization Mode
C-GBR 312027 GENERAL PHYSICS CORPORATION i
L These modes also correspond to the phases of the ILRT. Menu driven means that the user i
is presented with a list of options that the program can perform and from which the user can choose. It allows for interactive information exchange between the user and the computer and prevents invalid information or user mistakes from crashing the program.
y 1
Program organization consists of a master menu which controls access to the seven operating modes chained to the individual menus which control these modes. The data 4
processing, information display capabilities and function of each mode is as follows:
1.
Installation Mode: Used to install the volume weighting factors for RTD's, deweells, and pressure gauges; to install constants such as plant name, unit, volume, La value, number of sensors; to create and label the data files for modes 2 through 7 (above),
to enter names of test directors, computer operators and date of file origination.
2.
Pre Test Mode: ILRT measurement system burn-in, zero pressure testing, etc.
3.
Pressurization Mode: All data reduction, graphic displays of average temperature, dewpoint and corrected pressure.
3 4.
Stabilization Mode: All data reduction, automatic comparison of data against ANSI 56.8 and BN TOP 1 temperature stabilization criteria, notification when criteria is l
met, graphic displays of average temperature, dewpoint and corrected pressure.
5.
Test Mode: All data reduction, calculation of leakage rates using mass point, total time and point to point analysis techniques, display of trend report information required by BN TOP 1, graphic display of average temperature, dewpoint, pressure and mass, as well as graphic display of mass point measured leakage,95% UCL; i
total time measured and calculated leakage and the total time leakage rate at the 95% UCL (as calculated by BN TOP 1), including a superimposed acceptance criteria line).
l
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6.
Verification Test Mode: With input of imposed leakage in SCFM automatically l
calculates and displays on graph and trend report the acceptance criteria ban, plus all graphics displays available in test mode.
+
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GP;R 312027 GENERAL PHYSICS CORPORATION Other reduction and analysis capabilities of the General Physics ILRT computer program include:
~
1.
Containment total pressure conversion from counts to psia (if required), and
)
averaging.
2.
Containment drybulb temperature weighted averaging and conversion to absolute units.
3.
Containment dewpoint temperature weighted averaging (conversion from Foxboro dewcel element temperature to dewpoint temperature if required) and conversion to partial pressure of water vapor (psia).
4.
Data storage of ILRT measurement system inputs for each data point.
5.
Weight (mass) point calculations using the ideal gas law.
6.
Automated Data Acquisition and/or Manual Data Entry.
7.
Sensor performance and deviation information for sensor failure criteria, graphic display of individual sensor performance for selected operating mode.
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FAILED SENSOR DATA AND G!<APB
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-;.004 R T'D 5
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-0.520 RTD e=
-0.144 arO 9
-6.174 RTO 10 -
-0.611 RTD 11
-0.872 RTD 12 =
-0.971
+
=
>EW CELL DIF:ERENTIALS IN DEGREES FARENHEIT
. CELL-1 1.007 C CELL 2=
0.202 0 CELL
- =
-1.071
=
) CELL 4 =
0.594 D CELL 5=
0.27E D CELL 6=
-4.179
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-0.046 RTD 10 =
-0.036
=
OEW CELL DIFFERENTIALS IN DEGREES FARENHEIT D CELL 1=
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0.218 D CELL 3=
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AVG. SENSOR VALUE T 20 % )
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DATE TIl1E S(I) 301 18:30 74.449 i
301 18:45 73.811 301 19:00 75.400 j
301 19:15 79.945 301 19:30 80.943 301 19:45 80.912 301 20:00 81.062 301 20:15 01.091 301 20:30 01.047 301 20:45 79.069 301 21:00 76.22 301 21:15 73.065 301 21:30 72.625 301 21:45 72.79 301 22:00 73.153 301 22:15 74.325 301 22:30 75.500 301 22:45 78.137 301 23:00 78.955 301 23:15 77.18 301 23:30 78.283 301 23:45 79.129 302 00:00 79.043 302 00:15 79.824 302 00:30 79.916 302 00:45 79.068 302 01:00 77.65 302 01:15 76.06 302 01:30 75.074 302 01:45 75.1 302 02:00 74.968 302 02:15 73.716 300 02:30 73.005 302 02:45 72.305 302 03:00 72.326 302 03:15 73.222 302 03:30 75.441 302 03:45 78.137 302 04:00 75.065 302 04:15 73.471 302 04:30 77.305
-302 04:45 74.194 302 05:00 76.904 302 05:15 77.52 302 05:30 76.199 302 05:45 75.206 302 06:00 75.538 302 06:15 76.303 302 06:30 75.901 302 06:45 75.834 302 07:00 75.814
AVG. SENSOR VALUE T 20 ';
9 DATE TIME S(I) 302 07:15 75.040 302 07:30 75.000 302 07:45 75.73 302 00:00 75.025 302 00:15 75.943 302 00:30 75.793 302 00:45 75.042 302 09:00 75.799 302 09:15 75.799 302 09:30 75.752 302 09:05 75.827 302 10:00 75.709 302 10:15 75.689 302 10:30 75.671 300 10:45 75.788 302 11:00 75.72 302 11:15 75.77 302 11:30 75.697 e
302 11:45 75.705 302 12:00 75.683 302 12:15 75.782 302 12:30 75.672 302 12:45 75.666 302 13:00 75.659 302 13:15 75.744 302 13:30 75.695 302 13:45 75.717 302 14:00 75.633 302 14:15 75.622 302 14:30 75.718 302 14:45 75.654 302 15:00 75.555 302 15:15 75.541 302 15:30 75.606 302 15:45 75.7 302 16:00 75.668 302 16:15 75.582 302 16:30 75.643 300 16:45 75.631 O
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t e-t' APPENDIX G 1
LOCAL LEAKAGE TEST SUMMARIES
.r Y;
==
\\4 e
4
APPENDIX G PEACH BOTTOM UNIT 3 TYPE B TEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TEST LIAKAGE PENT TOTAL i
N0t DATE SCC 4AIN SCC / MIN DRYWELL HEAD 1/15/86 10 9/29/87 10 10/25/89 10 10 RPV STABILIZER ASEM.
9/3/87 10 (A THRU H) 6/29/89 10 10 N1 EQUIPMENT ACCESS HATCH 8/13/87 20 10/13/89 20 20 h
N2 PERSONNELAIRLOCK 8/2/86 1560 l
8/30/86 520 l
9/19/86 520 11/4/86 2078 1/7/86 530 4/2/87 1039 11/20/89 2152 11/23/89 1289 AIRLOCK 'O' RING 4/15/87 10 10/23/89 10 1299 N4 EADACCESS 1/15/86 10 1/29/88 10 l
9/19/89 10 l
10 N 6-CRD REMOVAL HATCH 2/24/86 10 4/23/86 100 9/11/87 10 10/27/89 10 10 N 7A MAIN STEAM LINE BELLOW
(*1) TOTAL FOR 8/26/87 273 N 7A,78,70,1D 6/23/89 260 9A,9B REPORTED UNDER 7A.
260 N 78 MAIN STEAM LINE BELLOWS
- 1 Page 1
APPENDtX G PEACH BOTTOM UNIT 3 TYPE B TEST
SUMMARY
1 PENT SYSTEM OR DESCRIPTION REMARKS TEST LEAKAGE PENT TOTAL PC DATE SCC / MIN SCC / MIN i
N 7C MAIN STEAM UNE BELLOWS
- 1 N.7D MAIN STEAM UNE BELLOWS
- 1 N 11 HPCI STEAM LINE BELLOWS (*2) TOTAL FOR 8/31/87 3013 N 11.12,13 A 6/23/89 40 14A,16A & 17 10/26/89 128 128 N 12 RHR SUCTION UNE BELLOW
- 2 N 13 A RHR PUMP DISCHARGE
- 2 BELLOW N 138 RHR PUMP DISCHARGE
(*3). TOTAL FOR 9/2/87 140 BELLOW N 138 & 16B 6/23/89 190 190 N 14 A RWCU SUCTION BELLOWS
- 2 N 16 A CORESPRAY BELLOWS
- 2 N 16B CORE SPRAYBELLOWS
- 2 N 25 AO 3505,3519,3520 8/28/87 20 O' RINGS 10/5/89 45 45 N 26 AO 3507,3506 'O' RINGS 8/21/87 10 10/6/89 10 11/9/89 20 20
_N 35 A G TIP PENETRATlON O' RING A-G TOGETHER 6/30/87 10 l
9/20/89 35 35 Page 2
4 APPENDIX G f
PEACH BOTTOM UNIT 3 TYPE BTEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TEST WAKAGE PENT TOTAL Not CATE SCC / MIN SCC / MIN N 100A ELECTRICAL
(*4) TOTAL FOR 8/31/87 20 N 100A,1000 11/1/88 35 104 A,1048,1040 7/11/89 20 104 D,105 A,1058 20 106 A,106 B,107 220 N 1000 EWCTRICAL
- 4 N 100D ELECTRICAL
(*S). TOTAL FOR 4/14/87 100 N 100D,100E, 7/11/89 20 1010,101 D,101 E,
20 103B,104 E,104 F 104 G,104 H,1050 105 D,105 E,1060, 106D N 100E EWCTRICAL
- 5 N 101 A ELECTRICAL
(*6) TOTAL FOR 9/2/87 30 N 101 A,101 B 7/11/89 20 101F,231 A,231 B 20 N 101 B ELECTRICAL
- 6 N 1010 EWCTRICAL
- 5 N 101 D ELECTRICAL
- 5 N 101 E ELECTRICAL
- 5 N 101 F ELECTRICAL
- 6 N 103B EWCTRICAL
- 5 N 104A ELECTRICAL
- 4 N 104B EWCTRICAL
- 4 N 104C EWCTRICAL
- 4 N 104D EWCTRICAL
- 4 Page 3
i APPENDIXG PEACH BOTTOM UNIT 3 TYPE B TEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TEST WAKAGE PENT TOTAL l
N 104E EWCTRICAL
- 5 i
N 104F EWCTRICAL
- 5 N 104G EWCTRICAL
- 5 j
N 104H EWCTRCAL
- 5 N 105A EWCTRICAL
- 4 i
N 105B ELECTRICAL
- 4 N 105C EWCTRICAL
- 5 N 105D ELECTRICAL
- 5 N 105E ELECTRICAL
- 5 N 106A ELECTRICAL
- 4 N 106B ELECTRICAL
- 4 N 106C ELECTRICAL
- 5 N 106D ELECTRICAL
- 5 N 107 ELECTRICAL
- 4
' N 150 TEST NOZZLE 12/7/87 10 6/27/S9 10 10
~
N 200A TORUS MANWAY N'E 1/7/86 20 N 200A TORUS MANWAY N'E 6/23/87 10 10/13/89 10 10 N 200B TORUS MANWAY S/W 1/10/86 20 1/19/86 20 1/31/86 20 6/26/87 20 10/27/89 10 11/8/89 10 10 Page 4
APPENDIX G PEACH BOTTOM UNIT 3 TYPE B TEST
SUMMARY
j PENT ' SYSTEMORDESCRIPTION REMARKS TEST LEAKAGE pet (T TOTAL Not CRTE SCC / MIN SCC / MIN N 201 A EXPANSION JOINT
('7) TOTAL FOR 9/3/87 55 N 201 A,2018 6/27/89 20 20 N 201 B EXPANSION JOINT
- 7
^
N 201C EXPANSION JOINT
(*8)-TOTAL FOR 9/4/S7 20 N 201C & 201D 6/23/89 20 20 N 201 D EXPANSION JOINT
- 8 N 201 E EXPANSION JOINT
('9) TOTAL FOR 9/4/87 116 N 201 E, 201 F 6/26/89 115 l
115 l
N.201 F EXPANSION JOINT
- 9 i
N 201G EXPANSION JOINT
('10) TOTAL FOR 9/4/87 20 N 201G,201 H 6/26/89 20 20 N.2 01 H EXPANSION JOINT
- 10 N 205A AO 2502B 'O' RING 1/16/86 20 AO-26B 'O' RING 1/16/86 20 1/18/86 20 7/17/87 20
-[
10/6/89 10 10 N 205B AO 3502A,AO 26A 4/14/87 20 AO 3521 A,AO 35218 10/6/89 230 O' RINGS 10/13/89 330 11/8/89 120 120 N 206A,B TORUS LEVEL INSTRUMENT 1/19/88 20 8/31/89 20 10/27/89 30 30 N 213A TORUS CONSTRUCTION 8/25/87 20 DRAINS 6/27/89 20 20 Page 5
APPENDIXG PEACH BOTTOM UNIT 3 TYPE B TEST
SUMMARY
I PENT SYSTEM OR DESCRIPTION REMARKS TEST EAKAGE PEffT TOTAL POL CATE SCC / MIN SCC / MIN N 213B TORUSCONSTRUCTION 8/25/87 20 DRAINS 6/27/89 20 20 N 219 AO 3511, AO 3512 8/26/87 10 U RINGS 10/10/89 10 10 l
N 220 ELECTRICAL
- 4 N 231 A ELECTRICAL
- 6 N 231B ELECTRICAL
- 6 N 250 TEST NOZZ DOUBLE 10/18/89 10 l
'O' RING 10 i
1 l
l i
i i
l
[
Page 6
-.--e
+
APPENDIXG PEACH BOTTOM UNIT 3 TYPE C TEST
SUMMARY
l PENT SYSTEM OR DESCRIPTION REMARKS TEST LEAKAGE PENT TOTAL i
NO.
N 7A MSIV 80A and 86A 80A 4/2/87 2511 L
86A 4/2/87 499 TOTALBOUNDARY 7/1/89 OFFSCALE 66A 7/28/89 295 TOTALBOUNDARY 8/8/89 450 450 N 7B MSIV 808 AND 86B 80B 4/2/87 2510 86B 4/28/87 783 TOTALBOUNDARY 7/1/89 OFFSCALE 86B
_7/28/89 5116 TOTALBOUNDARY 8/4/89 OFFSCALE TOTALBOUNDARY 8/5/80 4664 TOTALBOUNDARY 8/8/89 4250 4250 1'
N 7C MSIV 800 AND 86C 800 4/2/87 2409 860 4/2/87 1080 TOTALBOUNDARY 6/30/89 3461 TOTALBOUNDARY 7/1/89 5165 5165 l
N 7D MSIV 80D END 86D 80D 4/2/87 OFFSCALE 86D 4/2/87 2732 86D-5/13/87 1279 TOTALBOUNDARY 5/19/87 OFFSCALE 86D 5/22/87 519 TOTALBOUNDARY 5/27/87 4967 TOTALBOUNDARY 6/29/89 OFFSCALE 86D 7/13/89 517 TOTALBOUNDfRY 7/18/89 4137 TOTALBOUNDARY 7/21/89 3546 3546 N-8 MAIN STEAMLINE DRAINS 4/14/86 30 4/3/87 573 6/21/89 20 20 N 9A FEEDWATER CHK 96A 8/22/86 211 MO 23,19,20,21 8/22/86 2248 CHK 28A 9/28/87 611 CHK 96A 9/28/87 1641 Page 1
APPENDlXG PEACH BOTTOM UNIT 3 TYPEC TEST
SUMMARY
PENT SYSTEM OR DESCRIFYDON REMARKS TEST LEAKAGE PENT TOTAL Not DATE SCC / MIN SCC / MIN MO 23,19,20,21 11/3/87 2200 CSK 28A 7/11/89 OFFSCALE CHK 28A 7/13/89 340 CHK 28A 7/14/89 3003 CHK 96A 8/20/89 2227 MO 23,19,20,21 9/18/89 211 3003
_ N-98 FEED WATER MO 38B 1/30/86 1810 MO 21 10 CHK 28B 9/25/87 3373 CHK 968 9/26/87 2040 MO 13 20,21,30 11/5/87 94 CHK 28B 8/17/89 2853 CHK 968 8/17/89 1201 MO 13 20,21.30 10/11/89 613 2853 N-10 RCIC STEAM SUPPLY 7/20/86 50 7/22/86 OFFSCALE 7/26/86 OFFSCALE 7/27/86 OFFSCAE 7/28/86 5595 7/29/86 480 8/20/87 OFFSCAE MO 1315 ONLY 8/24/89 2256 l
9/14/89 40 11/14/89 20 20 N HPCI STEAM SUPPLY 8/18/87 8524 9/9/89 65 65 N 12 SHUTDOWN COOUNG 11/6/87 143 7/27/89 130-11/4/89 200 200 N-13 A
- B' RHR PUMP DISCHARGE MO-25B & 154B 11/20/87 2110 SV 5222 ONLY 11/25/87 10 AO 46B 8/18/89 7171 MO 25B 8/18/89 20 7181 Page 2
_. ~ -
APPENDIXG PEACH BOTTOM UNIT 3 J
TYPEC TEST Sl#A%RY PENT SYSTEM OR DESCRIPTK)N REMARKS-TEST LEAKAGE PENT TOTAL NO.
[%TE SCC / MIN SCC / MIN N 13B
'A' RHR PUMP DISCHARGE MO-25A & 154A 2/7/86 255 MO 10 25A 11/20/87 1064 MO 154A 11/20/87 1000 SV 5221 11/20/87 OFFSCALE SV 5221 11/25/87 2500 MO 25A 8/17/89 2014 AO-46A & 163A 8/17/89 1687 2014 N 14 RWCU SUCTION 3/7/86 167 9/24/87 9672 7/7/89 272 272 N 16 A
'A' CORE SPRAY LOOP SV 5224 4/29/86 83
(
8/27/87 20 MO-14128 ONLY 8/16/89 10 MO-14118 ONLY 8/16/89 7983 MO 1411B ONLY 8/19/89 1111 1111 N-16 B B CORE SPRAY 4/12/87 83 8/17/89 20 20 8/25/86 365 N 17 RPV HEAD SPRAY 12/21/87 105 VALVESREMOVED 7/14/89 20 20
~ N-18 D/W FLOOR DRAIN SUMP 1/31/86 690 DISH.
-10/26/87 1165
\\
10/4/89 2239 AO 20-83 ONLY 10/16/89 1823 AO 20 83 ONLY 10/18/89 306 599 N-19 D/W EQUIP DRAIN SUMP 1/31/86 317 DISH.
10/19/87 372 10/5/89 416 416 l
N-21 D/W SERVICE AIR 1/15/86 20 8/25/87 20 9/5/89 50 50 Page 3
APPENDIXG PEACH BOTTOM UNIT 3 TYPEC TEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TEST MAKAGE PENT TOTAL to DATE SCC / MIN SCC / MIN N 22 A INST N2 TO D/W 8/25/87 20 9/26/89 20 CHK 33202A 10/17/89 20 20 N 23 RBCCW D/W ISO VALVES 8/14/87 7864 5/30/89 670 l
670 N 24 RBCCW D/W ISO VALVES 8/14/87 338 5/30/89 20 20 N 25 D/W PURGE SUPPLY 8/5/87 236 8/28/87 45 10/5/89 245 10/13/89 460 460 N 26 PCAC SAMPLE 7/15/87 20 10/19/89 135 D/W PURGE EXHAUST T.T.OFF SCAG 8/20/87 OFFSCAE 10/5/89 40 10/20/89 10336 11/10/89 125 D/W PURGE EXHAUST 3/1/86 110 11/30/87 200 10/23/89 200
'B* CAD ANALYZER 8/11/87 760 10/20/89 75 535 N 32C ILRT TEST VALVES 4/26/88
-138 6/28/89 10 10 N 32D ILRT TEST VALVES 4/26/88 190 6/28/89 10 10 Page 4
)
APPENDIXG l
PEACH BOTTOM UNIT 3 l
TYPEC TEST
SUMMARY
- PEN'T SYSTEM OR DESCRIPTION REMARKS TEST LEAKAGE PENT TOTAL l
NOL CATE SCC / MIN '
SCC / MIN N 358
'D' TIP BALL VALVE 9/2/87 10 10/3/89 10 10 l
N 350 TIP PURGE SUPPLY 3/28/86 20 4/22/88 20 9/28/89 20 20 N 35D
'E' TIP BALL VALVE 9/2/87 10 10/3/89 10 11/18/89 60 60 N 35E
'C' TIP BALL VALVE 9/2/87 35 l
10/3/89 40 40 N 35F
'A' TIP BALL VALVE 9/3/87 28320 10/3/89 10 10 l
N 35G
- B' TIP BALL VALVE 9/2/87 10 l
10/3/89 10 10 1
N 39A
'A' CAD INJECTION 12/28/87 128 j
10/25/89 75 l
- B' CONTAINMENT SPRAY 3/11/88 20 6/12/89 346
)
l l
PACKING 7/28/89 10 l
421 1
l N-39B
'B' CAD INJECTION 8/11/87 601 10/24/89 3103 10/26/89 936
'A' CONTAINMENT SPRAY 2/5/86 897 l
3/3/88 186 6/10/89 911 l
1-Page 5 l
APPENDIX G PEACH BOTTOM UNIT 3 TYPEC TEST
SUMMARY
j i
PENT SYSTEM OR DESCRIFTION REMARKS TEST LEAKAGE PENT TOTAL i
to CATE SCC / MIN SCC / MIN MO 10 31 A PACKING 4/8/88 10 8/28/89 10 1857 N 41 RECIRC SAMPE VALVES 1/8/88 10 9/26/89 20 11/17/89 20 20 N 42 STANDBY LIOUID CONTROL XV 14A & B 9/1/87 20 9/29/89 20 CHECK VALVES 8/18/89 10 30 j
N-4 7 ADS BACKUP N2 SV 9130B 2/27/87 30 9/25/89 35 CHK 332998 8/27/87 30 9/25/89 10 45 N 51 A PCAC SAMPLE 7/2/87 20 SV 3671E & SV 3978E 10/14/89 85 85 N-518 PCACSAMPE 8/13/87 20 SV-3671D & SV 3978D 10/13/89 105 105 N 510 PCAC SAMPE 8/14/87 20 SV-3671C & SV 3978C 10/17/89 20 C CAD ANALYZER 8/3/87 20 SV 59610,59660,5960C 10/4/89 OFFSCAE 10/17/89 165 185 N 51 D PCAC SAMPLE DISCHARGE SV-3 70 3980 7/30/86 OFFSCAE 7/31/86 20 10/30/86 10' 11/14/86 114 8/19/87 OFFSCAE 10/19/87 5405 9/28/89 20 Page 6
__~
_m._..
APPENDIXG PEACH BOTTOM UNIT 3 i
~
WPE C TEST
SUMMARY
r
. PENT SYSTEM OR DESCRIMlON REMARKS TEST LEAKAGE PENT TOTAL NOL DATE SCC / MIN SCC / MIN CHK VALVE 4/17/86 1400 i
4/23/86 190 9/28/89 380 400 N 52F
'B' INST. NITROGEN CHK 33202B 8/26/86 20 8/26/87 10 AO 3969B 8/26/86 30 8/26/87 121 CHK-33202B &
9/28/89 60 HV 33310 10/3/89 20 CHK 33312 8 9/28/89 881 AO 39698 10/3/89 711 721 l
l N 53F D/W CHILL WATER MO 3201B 8/18/87 20 5/25/89 146 146 N 54 D/W CHILL WATER MO 32008 8/17/87 59 5/25/89 3574 3574 N-55 D/W CHILL WATER MO 3200B 8/17/87 333 5/25/89 3574 11/16/89 1554 1554 N 56 D/W CHILL WATER MO 3201 A 8/17/87 136 5/25/89 2911 2911 N 57 MAIN STEAM SAMPLE 2/10/86 OFFSCALE 3/11/86 610 2/24/88 143 9/28/89 350 350 Page 7
APPENDIX G PEACH BOTTOM UNIT 3 TYPEC TEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TEST WAKAGE PENT TOTAL
- Not CATE SCC / MIN SCC / MIN N 1028 D/W BREATHING AIR 8/28/87 44 8/28/89 50 ADS N2 SUPPLY 8/27/87 40 9/25/89 60 110 N 203 PCAC SAMPW 8/12/87 20 10/12/89 20 U CAD ANALYZER SV 5960D,5961D 8/6/87 290 l
5966D 10/17/89 40 l
60 t
N 205A TORUS VACCUM BREAKERS 1/16/86 20 1/16/86 180 1/17/86 130 l
1/18/86 20 i
1/20/86 40 7/17/87 85 10/13/89 20 20-N 205B TORUS VACCUM BREAKER 3/31/86 1360 3/31/86 170 8/22/86 120 8/22/86 90 8/24/86 130 8/5/87 300 8/19/87 40 10/6/89 551 10/30/89 5664 l
11/8/89 631 L
631 N 211 A
'A' CAD INJ.
1/2/86 472 N-210 A 12/3/87 575 10/24/89 20 B' TORUS COOL & SPRAY 3/4/88 2500 6/13/89 1468 PAR. MO-10-34B 9/8/89 20 Page 8 w
l APPENDIX G PEACH BOTTOM UNIT 3 l
TYPE C TEST
SUMMARY
PENT SYSTEM OR DESCRIPTION REMARKS TFST WAKAGE PENT TOTAL to CMTE SCC / MIN SCC / MIN PACKING 1/10/86 70 7/28/89 40 PAR. MO 10 34B 9/8/89 10 1498 l:
N 2118
- B' CAD INJ 1/9/86 30 N 2108 3/9/88 20 10/24/89 20
'A' TORUS COOL & SPRAY 2/6/86 4514 2/21/86 OFFSCAE 2/28/86 2847 3/10/88 692 6/13/89 3969 PACKING 11/8/88 170 L
8/28/89 200 4319 l
N 212 RCIC EXHAUST -
3/17/88 7131 J
9/18/89 8160 9/19/89 2212 RCIC EXHAUST DRAIN -
4/2/87 82 9/18/89 103 STOP CHECK U RING 9/3/87 10 l
9/7/89 10 l~
2325 N 214 HPCI EXHAUST T.T. - OFF SCALE 4/19/88 OFFSCALE 9/6/89 1812 l-HPCI EXHAUST DRAIN 8/18/87 350 9/20/89 561 STOP CHK O RING 3/7/87 10 9/6/89 10 2383 1
N 2178 RCIC VACUUM RELIEF 1/28/86 55 12/4/87 86 8/28/89 287 Page 9
e i
PEACH BOTTOM UNIT 3 TYPE C TEST
SUMMARY
j PENT SYSTEM OR DESCRIPTION REMARKS
-TEST LEAKAGE PENT TOTAL i
'F HPCI VACUUM RELIEF 3/4/86 20 1/12/88 520 8/29/89 194 481 N 218A INST N2 TO TORUS AO 3968 3/12/87 578 D/W VACUUM BKR.
9/23/87 350 9/27/89 330 10/20/89 150 CHECK VALVE 9/23/87 20 9/27/89 10 150 N 2188 PCAC SAMPLE SV 3671 A 8/14/87 20 10/12/89 40 SV 3978A 8/14/87 10 10/12/89 1001 10/20/89 10 40 N 218C ILRT TEST VALVES 4/26/88 1528 l -
6/28/89 10 10
- N 219 PCAC SAMPLE A/F TEST 10/11/89 30 10/11/89 50
'A' CAD ANALYZER 8/10/87 130 4
10/24/89 20 TORUS PURGE EXHAUST 8/26/87 20 10/10/89 20 TORUS PURGE EXHAUST 1/13/88 310 10/10/89 70 160 N 221 RCIC VACUUM PUMP 4/2/87 908 DISCHARGE 9/7/89 75 75
_ N 223 HPCI EXHAUST ORAIN 2/23/88 20 9/6/89 20 20 Page 10
h
~
APPENDIXG PEACH BOTTOM UNIT 3 1
TYPE C TEST
SUMMARY
)
l PEN'T SYSTEM OR DESCRIPTION REMARKS TEST LEAKAGE PENT TOTAL PC DATE SCC / MIN SCC / MIN l
N 225 RCK) PUMP SUCTION 8/20/87 22 8/6/89 7317 1
_I 8/8/89 1211 TORUS WATER CLEAN UP 8/21/87 20 8/5/89 717 1928 N 227 HPCI PUMP SUCTK)N 7/23/86 602 8/9/87-OFFSCALE 12/30/87 OFFSCALE 8/4/89 OFFF4 ALE 8/5/89 OFFSCALE 8/9/89 19824 8/21/89 OFFSCALE i
8/23/89 OFFSCALE 9/19/89 4798 9/20/89 76 76 N 2348 PASS LIOUiD RETURN 8/25/87 30 8/30/89 60 SCRAM DISCHARGE CV 32A 9/21/87 250 l
VOLUME VENT & DRAINS 6/7/89 75 l
CV 35A 9/21/87 20 3/7/89 20 h-CV 32B 9/21/87 260 6/7/89 215 CV 35B 9/21/87 410 6/7/89 175 CV-33 9/21/87 92 6/7/89 140 CV-36 9/21/87 1612 6/7/89 175 435 TOTAL MAX PATHWAY = 55426 cc/ min l
l l
Page 11 4